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<!-- Started     : 2014-01-01                                                                    -->
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<head>
  <title>GNU SPICE GUI - User Manual</title>
</head>

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<body>

<a name="TOP"></a>

<h1>
  <center>
    GNU SPICE GUI<br>
    User Manual
  </center>
</h1>

<hr>

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<h2><center>Table of Contents</center></h2>

<blockquote>

  1.    &nbsp; <a href="#INTRO"    > Introduction      </a><br><br>

  2.    &nbsp; <a href="#MNU_BAR"  > Menu Bar          </a>

  <blockquote>
    2.1 &nbsp; <a href="#MNU_FILE" > File Menu         </a><br>
    2.2 &nbsp; <a href="#MNU_SIM"  > Simulate Menu     </a><br>
    2.3 &nbsp; <a href="#MNU_SETGS"> Settings Menu     </a><br>
    2.4 &nbsp; <a href="#MNU_HELP" > Help Menu         </a>
  </blockquote>

  3.    &nbsp; <a href="#TOOL_BAR" > Tool Bar          </a><br><br>

  4.    &nbsp; <a href="#MAIN_WIN" > Main Window       </a>

  <blockquote>
    4.1 &nbsp; <a href="#LST_NODES"> Node List         </a><br>
    4.2 &nbsp; <a href="#LST_CPNTS"> Component List    </a><br>
    4.3 &nbsp; <a href="#NBK_ANA"  > Analysis Notebook </a><br>
    4.4 &nbsp; <a href="#NBK_TCTLS"> Console Notebook  </a><br>
    4.5 &nbsp; <a href="#STAT_BAR" > Status Bar        </a>
  </blockquote>

  5.    &nbsp; <a href="#TMP_FILES"> Temporary Files   </a>

</blockquote>

<br>
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<a name="INTRO"></a><h2>1. &nbsp; &nbsp; &nbsp; Introduction</h2>
<br>

<p>
  The name <b>gSpiceUI</b> is an abbreviation of the project title <i><b>GNU SPICE GUI</b></i>,
  which is itself an acronym standing for <b>G</b>nu is <b>N</b>ot <b>U</b>nix, <b>S</b>imulation
  <b>P</b>rogram with <b>I</b>ntegrated <b>C</b>ircuit <b>E</b>mphasis, <b>G</b>raphical <b>U</b>ser
  <b>I</b>nterface.
</p>

<p>
  gSpiceUI is intended to provide a GUI for freely available electronic circuit simulation engines
  ie. <b>NG-Spice</b> and <b>GnuCAP</b>. If the <b>gEDA</b> (<b>G</b>NU <b>E</b>lectronic
  <b>D</b>esign <b>A</b>utomation) tool set is used the utility <b>gnetlist</b> is used to convert
  schematic files to netlist files, <b>Gaw</b> or <b>Gwave</b> (no longer supported) display
  simulation results and <b>gschem</b> (part of the gEDA tool set) is the preferred schematic
  capture application. gSpiceUI is useless without the software tools it depends on, credit should
  go to the authors of those tools.
</p>

<p>
  gSpiceUI can also be used in conjunction with the <b>KiCAD</b> tool set. KiCAD doesn't expose it's
  netlist utility like gEDA so this step must be performed by the user inside the schematic capture
  application <b>eeschema</b>. The import mechanism in gSpiceUI cannot be used in this case and as
  yet eeschema can't be envoked inside gSpiceUI. Gaw and Gwave are used to display simulation
  results.
</p>

<p>
  The gSpiceUI GUI is designed to be as consistant as possible between analysis types and simulation
  engines. The intention is to abstract the technical particulars from the user so that the focus
  may be on the simulation rather than the simulation engine or even the analysis type.
</p>

<p>
  Like all open source software gSpiceUI is a work in progress and probably always will be. It has
  been developed over a long period of time (since 2003) and has reached a relatively mature state.
  Experience in software development as well as using software in general has taught me that it's
  better to provide less functionality that works than more functionality that just promises a lot.
  Consequently, as a generally rule, bugs fixes and improvements to the underlying architecture will
  take precedence over new functionality. I believe this approach pays off in the long term.
</p>

<p>
  It is worth noting that whereas NG-Spice is derived from the SPICE code base, GNU-Cap is not.
  GNU-Cap is an independent implementation of the principals used to analyses electronic circuits.
  As a consequence analysis results can be generated using two independant mechanisms and then
  compared. This is one of the reasons for supporting more than one simulation engine; if the same
  or similar results can be achieved using two different simulation engines then it's likely that
  the simulation results will bear some resemblence to what actually happens in reality.
</p>

<p>
  It is important to realise that a simulation engine <b><i>models</i></b> the behaviour of a system
  and therefore can never be 100% accurate. In addition the simulation engine itself is an
  implementation in software of a mathematical model and so is also subject to bugs. As the
  underlying mathematical model and software implementation improve the simulation performance
  improves. One of the reasons for the choice of simulation engines to support was that they are
  both in constant development. (Not to mention the inherent goodness and righteousness of open
  source software, so I won't mention it.)
</p>

<p>
  The skills and judgement of the user have a profound impact on the usefulness of electronic
  simulation. It can be a technically demanding process requiring considerable thought, practice and
  persistence. The alternative is to go straight to building prototypes; in any case, ultimately
  prototypes must be created to finalize a design. However simulation is generally a rewarding step
  in the development process, even if it only provides a better understanding of the internal
  workings of a design.
</p>

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<a name="MNU_BAR"></a><h2>2. &nbsp; &nbsp; &nbsp; Menu Bar</h2>
<br>

<p>
  The menu bar provides access to almost all of the functionality provided by gSpiceUI. However
  there are a few functions that can only be accessed via command line options.
</p>

<a name="MNU_FILE"></a><h3>2.1 &nbsp; &nbsp; File Menu</h3>

<p>
  This file menu contains options mainly associated with handling netlist and schematic files.
</p>

<h4>2.1.1 &nbsp; Open</h4>

<p>
  Open a netlist (circuit description) file containing component definitions and load it into the
  NetList text control. If the netlist contains simulation instructions gSpiceUI attempts to parse
  them and the settings are displayed in the GUI.
</p>

<p>
  Notes :
</p>
<ul>
  <li>
    Be aware that gSpiceUI will modify the netlist file; it will change the formatting and remove
    things it doesn't understand. If this isn't OK, create a copy of the netlist file and give that
    to gSpiceUI.
  </li>
  <li>
    When using the gEDA tool set the netlist file extension is ".ckt". For the KiCAD tool set the
    netlist extension is "cir". Be sure to specify the appropriate file extension for the tool set.
  </li>
  <li>
    There is an upper limit to the number of lines which may be displayed in any text control (the
    underlying file isn't truncated). This setting maybe adjusted by the user, refer to
    <i>2.3.2 Preferences Dialog</i>.
  </li>
</ul>

<h4>2.1.2 &nbsp; Import</h4>

<p>
  Import one or more schematic files. The utility gnetlist is used to convert the schematic file/s
  to a single netlist file. The netlist file name is automatically derived from the first schematic
  file name in the list with the file extension changed to ".ckt". Eg. if schem1.sch, schem2.sch,
  schem3.sch were specified as the schematic file names to be imported the netlist file name would
  be schem1.ckt.
</p>

<p>
  Notes :
</p>
<ul>
  <li>
    If you are using the KiCAD tool set Import won't work. The gEDA utility gnetlist can't convert
    KiCAD schematics to a netlist file. The netlist utility in KiCAD is built into the schematic
    capture application eeshema so gSpiceUI can't envoke it. The netlist file must be created or
    updated from within eeshema by the user and reloaded into gSpiceUI using the Reload operation.
    
  </li>
</ul>

<h4>2.1.3 &nbsp; Reload</h4>

<p>
  Reload the netlist file. If the netlist was imported from one or more schematic files, the import
  operation will be repeated. As far as possible the simulation settings shown in the currently
  displayed analysis notebook page are retained.
</p>

<p>
  When gSpiceUI is used to create a netlist file from schematic file/s it inserts a reference to the
  schematic file/s near the beginning of the netlist file. If the currently open netlist has this
  schematic reference, reload performs an import operation otherwise the netlist is simply reloaded.
  In either case the simulation settings shown in the currently displayed analysis notebook page are
  retained as far as possible.
</p>

<h4>2.1.4 &nbsp; Close</h4>

<p>
  If a netlist file is open then close it and resets all GUI parameters to default values.
</p>

<h4>2.1.5 &nbsp; Quit</h4>

<p>
  Close all files and child applications, delete temporary files if required and exit the
  application.
</p>

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<a name="MNU_SIM"></a><h3>2.2 &nbsp; &nbsp; Simulate Menu</h3>

<p>
  The simulate menu contains options associated with circuit simulation operations and provides
  access to other useful applications upon which gSpiceUI dependends.
</p>

<h4>2.2.1 &nbsp; Create</h4>

<p>
  Create a simulation file based on the values currently displayed on the GUI or the contents of the
  Simulation text control. Note, any changes made to the GUI have priority over changes made by the
  user to the Simulation text control contents.
</p>

<p>
  If any changes are made to the GUI control contents the simulation file is completely
  re-constructed, which then causes the Simulation control contents to be over-written and lost.
  However, if changes have been made to the Simulation text control contents alone then it is
  written verbatim to the simulation file.
</p>

<p>
  If a problem is encountered a message box is displayed giving a brief explanation as to why the
  operation could not be completed. The raw console spew generated by the process will have been
  sent to the Console text control, a careful perusal of this generally reveals the cause of the
  problem/s.
</p>

<h4>2.2.2 &nbsp; Run</h4>

<p>
  Run a simulation based on the values currently displayed on the GUI controls or in the Simulation
  text control. If the user has made changes since the last Create operation then a Create operation
  is automatically executed as described above.
</p>

<p>
  If the simulation file is created successfully then gSpiceUI attempts to run the simulation. The
  simulation results are formatted then sent to a data file (refer to section 5. Files) and are
  displayed in the appropriate Simulation Results text control.
</p>

<p>
  If a problem is encountered a message box is displayed giving a brief explanation as to why the
  operation could not be completed. The raw console spew generated by the process will have been
  sent to the Console text control, a careful perusal of this generally reveals the cause of the
  problem/s.
</p>

<h4>2.2.3 &nbsp; Stop</h4>

<p>
  Stop a running simulation immediately. This option can only be executed if a simulation is
  actually running. This is a useful option if a simulation is running too long or appears as if it
  won't converge.
</p>

<h4>2.2.4 &nbsp; Schematic</h4>

<p>
  Edit a schematic file. If there is a schematic file associated with an open netlist file it is
  opened using gschem and may be viewed or edited by the user. Note : if changes are made to the
  schematic file (and the schematic file has been updated on disk by gschem) then an Import
  operation must be performed in gSpiceUI in order for gSpiceUI to "know" about new the changes.
</p>

<p>
  It's important to be aware that gSpiceUI cannot run a simulation based on any old schematic file
  eg. generated by gschem. In fact, the simulation will fail unless the schematic is trivial or
  you're just lucky. Certain prerequisites must be met before a schematic may be simulated. The
  schematic must be translated into a form which can be interpreted by the simulation engine (eg. by
  gnetlist), in short everything must be explicitly defined. The extra information required over
  that sufficient for human readability is :
</p>

<p>
  <ul>
    <li>
      At present if the KiCAD tool set is used this function will not work. The KiCAD schematic
      capture application eeschema must be manually started by the user and the netlist file updated
      by the user from within eeschema whenever the schematic is changed. Perform a Reload operation
      and then proceed as normal.
    </li>
    <li>
      All power supply sources must be explicitly defined.
    </li>
    <li>
      All signal sources must be explicitly defined.</li>
    <li>
      Components not already defined in the simulation environment must be defined using models.
    </li>
    <li>
      Component labels must adhere to the rules specified for the simulation engine eg. resistor
      names always start with the letter 'R'. In particular be aware that often a model file
      contains a sub-circuit which must have a name starting with the character 'X'.
    </li>
    <li>
      Net labels must adhere to the rules specified for the simulation engine eg. they can't start
      with a digit. Refer to the specific simulation engine documentation.
    </li>
  </ul>
</p>

<p>
  Notes :
</p>
<ul>
  <li>
    In gschem, models may be included by setting the component's file attribute or by use of a SPICE
    Model object. Either way the component value is set to the model or sub-circuit label. Check the
    example schematics that come with gSpiceUI to see how it's done eg. the LM555 or operational
    amplifier examples.
  </li>
  <li>
    gSpiceUI recognizes a component type by the first letter of the component name eg. an inductor
    name is expected to start with the letter 'L'. The following is list of the first letter of
    various component types (this format is derived from NG-Spice) :
    <table cellspacing=0 cellpadding=0>
      <tr><td>&nbsp; &nbsp;</td><td>&nbsp; &nbsp; &nbsp;</td><td>&nbsp; &nbsp;</td><td></td></tr>
      <tr><td></td><td>B</td><td>-</td><td>Non-Linear Dependent Source</td></tr>
      <tr><td></td><td>C</td><td>-</td><td>Capacitor</td></tr>
      <tr><td></td><td>D</td><td>-</td><td>Diode</td></tr>
      <tr><td></td><td>E</td><td>-</td><td>Voltage Controlled Voltage Source</td></tr>
      <tr><td></td><td>F</td><td>-</td><td>Current Controlled Current Source</td></tr>
      <tr><td></td><td>G</td><td>-</td><td>Voltage Controlled Current Source</td></tr>
      <tr><td></td><td>H</td><td>-</td><td>Current Controlled Voltage Source</td></tr>
      <tr><td></td><td>I</td><td>-</td><td>Independent Current Source</td></tr>
      <tr><td></td><td>J</td><td>-</td><td>JFET (Junction Field-Effect Transistor)</td></tr>
      <tr><td></td><td>K</td><td>-</td><td>Coupled (Mutual) Inductors</td></tr>
      <tr><td></td><td>L</td><td>-</td><td>Inductor</td></tr>
      <tr><td></td><td>M</td><td>-</td><td>MOSFET (Metal-Oxide Semiconductor Field-Effect Transistor)</td></tr>
      <tr><td></td><td>O</td><td>-</td><td>Lossy Transmission Line (LTRA)</td></tr>
      <tr><td></td><td>P</td><td>-</td><td>Coupled Multi-conductor Transmission Line (CPL)</td></tr>
      <tr><td></td><td>Q</td><td>-</td><td>BJT (Bipolar Junction Transistor)</td></tr>
      <tr><td></td><td>R</td><td>-</td><td>Resistor</td></tr>
      <tr><td></td><td>S</td><td>-</td><td>Voltage Controlled Switch</td></tr>
      <tr><td></td><td>T</td><td>-</td><td>Lossless Transmission Line</td></tr>
      <tr><td></td><td>U</td><td>-</td><td>Uniform Distributed RC Transmission Line (URC)</td></tr>
      <tr><td></td><td>V</td><td>-</td><td>Independent Voltage Source</td></tr>
      <tr><td></td><td>W</td><td>-</td><td>Current Controlled Switch</td></tr>
      <tr><td></td><td>X</td><td>-</td><td>Sub-circuit</td></tr>
      <tr><td></td><td>Y</td><td>-</td><td>Single Lossy Transmission Line (TXL)</td></tr>
      <tr><td></td><td>Z</td><td>-</td><td>MESFET (Metal-Semiconductor Field Effect Transistor)</td></tr>
    </table>
  </li>
</ul>

<h4>2.2.5 &nbsp; View Results</h4>

<p>
  View simulation results in a graphical form. One of the simulation results files is opened using a
  data viewer application eg. Gaw or Gwave. The particular results file loaded into the viewer
  process dependents on the currently selected simulation results tab and analysis type
  tab.
</p>

<br>
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<a name="MNU_SETGS"></a><h3>2.3 &nbsp; &nbsp; Settings Menu</h3>

<p>
  The settings menu contains application configuration options.
</p>

<h4>2.3.1 &nbsp; Simulation Engine Selection</h4>

<p>
  The first section of the Settings Menu contains radio buttons allowing the selection of the
  electronic circuit simulation engine to be used. The analysis notebook is updated based on the
  chosen simulation engine, the selected simulation engine name is displayed in the status line and
  any simulation results are sent to the appropriate console tab.
</p>

<p>
  When the simulation engine is changed gSpiceUI attempts to transfer simulation information to the
  new simulator environment. The information is tranferred via the simulation file so if information
  appears on the GUI but not in the simulation file it will be lost. If this is a problem create a
  fresh simulation file prior to changing the simulation engine.
</p>

<h4>2.3.2 &nbsp; Preferences Dialog</h4>

<p>
  The preferences dialog contains the following settings :
</p>

<ul>
  <li>
    Waveform data viewer :<br>
      A choice box containing the available waveform data viewer utilities. The currently selected
      waveform data viewer utility name is displayed in the status line.
      <br>&nbsp;
  </li>
  <li>
    Temporary files :<br>
      A choice box containing the available temporary file management strategies, ie. automatically
      delete temporary files, prompt the user or just keep the temporary files. Most of the files in
      question contain simulation results data and may be useful outside gSpiceUI. Refer to section
      <a href="#TMP_FILES">5.&nbsp;Temporary&nbsp;Files</a>.
      <br>&nbsp;
  </li>
  <li>
    Main frame layout :<br>
      A choice box containing the available main frame layout schemes. The main has two layout
      schemes to choose from : longer probes (Nodes and Component) controls or a wider console
      notebook control.
      <br>&nbsp;
  </li>
  <li>
    Phase / angle units :<br>
      A choice box containing the available phase or angle units, ie. degrees or radians.
      <br>&nbsp;
  </li>
  <li>
    Results precision :<br>
      A choice box containing the available precisions which may be applied to simulation results.
      The data are rounded to the selected precision not just truncated.
      <br>&nbsp;
  </li>
  <li>
    gnetlist Guile backend :<br>
      A choice box containing the available gnetlist Guile backend procedures. This list of Guile
      backends is derived by querying gnetlist directly so whatever procedures gnetlist can detect
      are listed.
      <br>&nbsp;
  </li>
  <li>
    Max text control lines :<br>
      A value control which sets the maximum number of lines which may be displayed in any of the
      console text controls. Simulation results files can potentially be very large, this value
      allows the user to have some control over the system resources used by gSpiceUI.
      <br>&nbsp;
  </li>
  <li>
    Spin control period :<br>
      A value control which sets the period (in msec) between successive spin button control
      updates.
      <br>&nbsp;
  </li>
  <li>
    Tool tip delay :<br>
      A value control which sets the delay (in msec) before a tool tip is displayed.
      <br>&nbsp;
  </li>
  <li>
    Show tool tips :<br>
      A check box which enables or disables tool tips.
      <br>&nbsp;
  </li>
  <li>
    Sync. sweep sources :<br>
      A check box which enables or disables synchronization of the sweep sources. If a sweep source
      is selected in one analysis page, where possible the same source will appear in other analysis
      pages. Note : the sweep source value is not carried over between pages (I'm not convinced this
      behaviour would be helpful).
      <br>&nbsp;
  </li>
  <li>
    Sync. temperatures :<br>
      A check box which enables or disables synchronization of the ambient temperature values
      between analysis pages and the OPTIONS dialogue.
      <br>&nbsp;
  </li>
  <li>
    Keep the netlist file :<br>
      A check box which controls whether netlist files are included in the list of temporary files
      and therefore the temporary file management strategy.
      <br>&nbsp;
  </li>
  <li>
    gnetlist verbose mode :<br>
      A check box which enables or disables gnetlist verbose mode. With this enabled gnetlist
      generates lots of lovely console spew which appears in the Console tab of the console
      notebook. It's useful for debugging when gnetlist is have problems importing schematic file/s.
      <br>&nbsp;
  </li>
  <li>
    Include model defs. :<br>
      A check box which controls whether .INCLUDE directives are used for model files or the model
      file contents are inserted in the netlist file. )This option controls the the gnetlist SPICE
      backend "include_mode".)
      <br>&nbsp;
  </li>
  <li>
    Embed include files :<br>
      A check box which controls how gnetlist behaves when it encounters a .INCLUDE directive. With
      this option checked gnetlist embeds (inserts) the file contents into the netlist file. (This
      option controls the the gnetlist SPICE backend "embedd_mode".)
      <br>&nbsp;
  </li>
  <li>
    Fix component prefixes :<br>
      A check box which controls whether component label prefixes are automatically tested and
      modified if the incorrect prefix is used. SPICE recognizes different components based on the
      first character of the component label eg. R1 would be identified as a resistor. If an
      incorrect prefix is detected the correct prefix is prepended to the component label. (This
      option controls the the gnetlist SPICE backend "nomunge_mode".)
      <br>&nbsp;
  </li>
  <li>
    The paths to the various programs and utilities used by gSpiceUI may be manually set via this
    menu selection. (Not yet implemented)
  </li>
</ul>

<p>
  Note :
</p>
<ul>
  <li>
    All preferences work if the gEDA tool set is used but some aren't pertinent if the KiCAD tool
    set is used.
  </li>
</ul>

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<a name="MNU_HELP"></a><h3>2.4 &nbsp; &nbsp; Help Menu</h3>

<p>
  The Help Menu contains the following options :
</p>

<h4>2.4.1 &nbsp; User Manual</h4>

<p>
  Open the gSpiceUI HTML documentation in a HTML view window (more specifically this document). At
  the time of writing the HTML viewer only performs the basic functions (eg. it is monochrome) but
  it is sufficient for the purpose.
</p>

<h4>2.4.2 &nbsp; About</h4>

<p>
  Open a dialogue containing application "About" information.
</p>

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<a name="TOOL_BAR"></a><h2>3. &nbsp; &nbsp; &nbsp; Tool Bar</h2>
<br>

<p>
  The tool bar contains buttons which give easy access to the most used functions. The buttons are
  presented in groups associated with the different types of activities. Refer to the matching menu
  bar function in section <a href="#MNU_BAR">Menu&nbsp;Bar</a>.
</p>

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<a name="MAIN_WIN"></a><h2>4. &nbsp; &nbsp; &nbsp; Main Window</h2>
<br>

<p>
  The main window is made up of various display objects which are described in the following
  sub-sections. There are lists of possible test points, analysis settings, console output and a
  status bar.
</p>

<p>
  The main window title bar always contains at least the application name. If a file is open,
  whether it be a netlist or schematic file/s, the name of a netlist file will be appended to the
  normal window title banner. Keep in mind that this netlist file is the main file that gSpiceUI
  works on.
</p>

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<a name="LST_NODES"></a><h3>4.1 &nbsp; &nbsp; Node List</h3>

<p>
  Display the list of node labels extracted from the netlist file. One or more nodes may be selected
  (or deselected) by clicking on the node/s in the list with the mouse. The probes for the selected
  nodes will be calculated and included in the simulation results.
</p>

<p>
  A single node may be selected from the list by left clicking on it with the mouse. To select
  multiple nodes press the control key and left click on the desired nodes with the mouse. To select
  a range of nodes left click on the desired range with the mouse while holding down the shift key.
</p>

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<a name="LST_CPNTS"></a><h3>4.2 &nbsp; &nbsp; Component List</h3>

<p>
  Display the list of components extracted from the netlist file. One or more components may be
  selected (or deselected) by clicking on the component/s in the list with the mouse. The probes for
  the selected components will be calculated and included in the simulation results. At present only
  two terminal components are included in this list.
</p>

<p>
  A single component may be selected from the list by left clicking on it with the mouse. To select
  multiple components press the control key and left click on the desired components with the mouse.
  To select a range of components left click on the desired range with the mouse while holding down
  the shift key.
</p>

<br>
<a href="#TOP"><center>Return to top</center></a>

<hr size="1" width="80%" align="center">

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<a name="NBK_ANA"></a><h3>4.3 &nbsp; &nbsp; Analysis Notebook</a></h3>

<p>
  There are two mildly different analysis notebooks associated with the two simulation engines
  supported by gSpiceUI ie. GNU-Cap or NG-Spice. Each analysis notebook contains analysis pages
  reflecting the various analysis types supported by the associated simulation engine. The following
  brief outlines the various analysis types current supported. For further information refer to the
  user documentation for the appropriate simulation engine (much of what follows is taken from this
  documentation).
</p>

<h4>4.3.1 &nbsp; Operating Point Analysis</h4>

<b>NG-Spice :</b>

<blockquote>
  This analysis type is supported using the DC command in NG-Spice. The DC analysis determines the
  DC operating point of the circuit with inductors shorted and capacitors opened. In this instance
  the DC analysis is used to generate DC transfer curves for temperature stepped over a
  user-specified range and the DC output variables are stored for each sequential temperature value.
</blockquote>

<b>GNU-Cap :</b>

<blockquote>
  Performs a nonlinear DC steady state analysis. If a temperature range is given, it sweeps the
  temperature. If there are numeric arguments, they represent a temperature sweep. They are the
  start and stop temperatures in degrees Celsius, and the step size, in order. This command also
  sets up the quiescent point for subsequent AC analysis. It is necessary to do this for nonlinear
  circuits. The last step in the sweep determines the quiescent point for the AC analysis.
</blockquote>

<h4>4.3.2 &nbsp; DC Analysis</h4>

<b>NG-Spice :</b>

<blockquote>
  The DC analysis determines the DC operating point of the circuit with inductors shorted and
  capacitors opened. A DC analysis is automatically performed prior to a Transient analysis to
  determine the transient initial conditions, and prior to an AC small-signal analysis to determine
  the  linearized, small-signal models for nonlinear devices. The DC analysis can also be used to
  generate DC transfer curves : a specified independent voltage, current source, resistor or
  temperature is stepped over a user-specified range and the DC output variables are stored for each
  sequential source value.
</blockquote>

<b>GNU-Cap :</b>

<blockquote>
  Performs a nonlinear DC steady state analysis, and sweeps the signal input, or a component value.
  If there are numeric arguments, without a part label, they represent a ramp from the generator
  function. They are the start value, stop value and step size, in order. In some cases, you will
  get one more step outside the specified range of inputs due to internal rounding errors. The last
  input may be beyond the end point. The program will sweep any simple component, including
  resistors, capacitors, and controlled sources.
</blockquote>

<h4>4.3.3 &nbsp; AC Analysis</h4>

<b>NG-Spice :</b>

<blockquote>
  The AC small-signal analysis determines the output variables as a function of frequency. The DC
  operating point of the circuit is first determined and used to generate linearized, small-signal
  models for all of the nonlinear devices in the circuit. The resultant linearized version of the
  circuit is then analyzed over a user-specified range of frequencies. The desired output of an AC
  small-signal analysis is usually a transfer function (trans-impedance, voltage gain, etc.). If the
  circuit has only one AC input, it is convenient to set that input to unity and zero phase, so that
  output variables have the same value as the transfer function of the output variable with respect
  to the input.
</blockquote>

<b>GNU-Cap :</b>

<blockquote>
  Performs a small signal, steady state, AC analysis. Sweeps frequency. The AC command does a linear
  analysis about an operating point. It is absolutely necessary to do an OP analysis first on any
  nonlinear circuit. Not doing this is the equivalent of testing it with the power off. If the start
  frequency is zero, the program will still do an AC analysis. The actual frequency can be
  considered to be the limit as the frequency approaches zero. It is, therefore, still possible to
  have a non-zero phase angle, but delays are not shown because they may be infinite.
</blockquote>

<h4>4.3.4 &nbsp; Transient Analysis</h4>

<b>NG-Spice :</b>

<blockquote>
  The Transient analysis determines the transient output variables as a function of time over a
  user-specified time interval. The initial conditions are automatically determined by a DC
  analysis. All sources which are not time dependent (for example, power supplies) are set to their
  DC value.
</blockquote>

<b>GNU-Cap :</b>

<blockquote>
  Performs a nonlinear time domain (transient) analysis. Do not use a step size too large as this
  will result in errors in the results. If you suspect that the results are not accurate, try a
  larger argument to skip. This will force a smaller internal step size. If the results are close to
  the same, they can be trusted. If not, try a still larger skip argument until they appear to match
  close enough. The most obvious error of this type is aliasing. You must select sample frequency at
  least twice the highest signal frequency that exists anywhere in the circuit. This frequency can
  be very high, when you use the default step function as input. The signal generator does not have
  any filtering.
</blockquote>

<h4>4.3.5 &nbsp; Fourier Analysis</h4>

<b>NG-Spice :</b>

<blockquote>
  Not yet implemented.
</blockquote>

<b>GNU-Cap :</b>

<blockquote>
  Performs a nonlinear time domain (transient) analysis, but displays the results in the frequency
  domain. Actually, this command does a nonlinear time domain analysis, then performs a Fourier
  transform on the data to get the frequency data. The transient analysis parameters (start, stop,
  step) are determined by the program as necessary to produce the desired spectral results. The
  internal time steps are selected to match the Fourier points, so there is no interpolation done.
</blockquote>

<br>
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<hr size="1" width="80%" align="center">

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<a name="NBK_TCTLS"></a><h3>4.4 &nbsp; &nbsp; Text Control Notebook</h3>

<p>
  The console notebook contains various text controls which display text data generated by the
  different operations initiated by gSpiceUI.
</p>

<h4>4.4.1 &nbsp; Console</h4>

<p>
  Display the console input/output for the last process executed by gSpiceUI. If an error occurs
  this is a good place to look for indications of what has gone wrong.
</p>

<h4>4.4.2 &nbsp; Circuit</h4>

<p>
  Display the raw netlist file which was opened or imported via the file menu. The variables and
  values contained in the netlist file are those displayed in the GUI's display objects.
</p>

<h4>4.4.3 &nbsp; Simulation</h4>

<p>
  Display the simulation file to be run. It is basically the netlist file plus simulator commands
  based on user input to the GUI objects. It can be manually edited by the user and will be run as
  is if the Run button is pressed. NOTE : if the create button is pressed the contents of this tab
  will be over-written destroying any user input.
</p>

<h4>4.4.4 &nbsp; NG-Spice Results</h4>

<p>
  Display the results from the last run of the NG-Spice simulation engine. The raw data is
  reformatted to aid readability; non-data records are removed and the precision is set according
  the value set in the Preferences dialog. If required the raw output from the simulation engine may
  be viewed in the Console tab.
</p>

<h4>4.4.5 &nbsp; GNU-Cap Results</h4>

<p>
  Display the results from the last run of the GNU-Cap simulation engine. The raw data is
  reformatted to aid readability; non-data records are removed and the precision is set according
  the value set in the Preferences dialog. If required the raw output from the simulation engine may
  be viewed in the Console tab.
</p>

<br>
<a href="#TOP"><center>Return to top</center></a>

<hr size="1" width="80%" align="center">

<!------------------------------------------------------------------------------------------------->

<a name="STAT_BAR"></a><h3>4.5 &nbsp; &nbsp; Status Bar</h3>

<p>
  The status bar is located at the bottom of the application main frame. It consists of three panes
  which contain text messages showing the state of gSpiceUI. From left to right the panes contain :
</p>

<p>
<ol>
  <li> The last application status or error message.</li>
  <li> The currently selected simulation engine.</li>
  <li> The currently selected waveform viewer utility.</li>
</ol>
</p>

<br>
<a href="#TOP"><center>Return to top</center></a>

<hr size="5">

<!------------------------------------------------------------------------------------------------->

<a name="TMP_FILES"></a><h2>5. &nbsp; &nbsp; &nbsp; Temporary Files</h2>
<br>

<p>
  Whilst running gSpiceUI various temporary files may be generated in the directory occupied by the
  schematic or netlist file/s. To illustrate, consider the situation where the schematic file
  "test-cct.sch" is imported and every possible analysis type is run, using both NG-Spice and
  GNU-Cap. Along with the schematic file the following temporary files which would be created :
</p>

<blockquote>
  <table cellspacing=0 cellpadding=0>

    <tr>
      <td>&lt;path&gt;/sch/test-cct.sch</td><td></td>
      <td>(The schematic file to be analysed)</td>
    </tr>

    <tr><td>&nbsp;</td><td>&nbsp; &nbsp; &nbsp;</td><td>&nbsp;</td></tr>

    <tr>
      <td>&lt;path&gt;/sch/test-cct.ckt</td>       <td></td>
      <td>(Netlist file with simulation commands)</td>
    </tr>
    <tr>
      <td>&lt;path&gt;/sch/test-cct.sch~</td>      <td></td>
      <td>(Backup file to the schematic file)</td>
    </tr>
    <tr>
      <td>&lt;path&gt;/sch/gspiceui.log</td>        <td></td>
      <td>(Temporary file for raw process output)</td>
    </tr>

    <tr><td>&nbsp;</td><td></td><td></td></tr>

    <tr>
      <td>&lt;path&gt;/sch/test-cct.ngspice.op</td><td></td>
      <td>(Results file - operating point analysis)</td>
    </tr>
    <tr>
      <td>&lt;path&gt;/sch/test-cct.ngspice.dc</td><td></td>
      <td>(Results file - DC analysis)</td>
      </tr>
    <tr>
      <td>&lt;path&gt;/sch/test-cct.ngspice.ac</td><td></td>
      <td>(Results file - AC analysis)</td>
    </tr>
<!-- <tr>
       <td>&lt;path&gt;/sch/test-cct.ngspice.di</td><td></td>
       <td>(Results file - distortion analysis)</td>
     </tr> -->
<!-- <tr>
       <td>&lt;path&gt;/sch/test-cct.ngspice.no</td><td></td>
       <td>(Results file - noise analysis)</td>
     </tr> -->
<!-- <tr>
       <td>&lt;path&gt;/sch/test-cct.ngspice.pz</td><td></td>
       <td>(Results file - pole-zero analysis)</td>
     </tr> -->
<!-- <tr>
       <td>&lt;path&gt;/sch/test-cct.ngspice.se</td><td></td>
       <td>(Results file - sensitivity analysis)</td>
     </tr> -->
    <tr>
      <td>&lt;path&gt;/sch/test-cct.ngspice.tr</td><td></td>
      <td>(Results file - transient response analysis)</td>
    </tr>
<!-- <tr>
       <td>&lt;path&gt;/sch/test-cct.ngspice.tf</td><td></td>
       <td>(Results file - transfer function analysis)</td>
    </tr> -->

    <tr><td>&nbsp;</td><td></td><td></td></tr>

    <tr>
      <td>&lt;path&gt;/sch/test-cct.gnucap.op</td> <td></td>
      <td>(Results file - operating point analysis)</td>
    </tr>
    <tr>
      <td>&lt;path&gt;/sch/test-cct.gnucap.dc</td> <td></td>
      <td>(Results file - DC analysis)</td>
    </tr>
    <tr>
      <td>&lt;path&gt;/sch/test-cct.gnucap.ac</td> <td></td>
      <td>(Results file - AC analysis)</td>
    </tr>
    <tr>
      <td>&lt;path&gt;/sch/test-cct.gnucap.tr</td> <td></td>
      <td>(Results file - transient response analysis)</td>
    </tr>
<!-- <tr>
      <td>&lt;path&gt;/sch/test-cct.gnucap.fo</td> <td></td>
      <td>(Results file - fourier analysis)</td>
    </tr> -->

  </table>
</blockquote>

<p>
  All file names begin with the prefix "test-cct" (taken from the schematic file name). File name
  extensions then depend on the file type. Files containing simulation results include the name of
  the simulation engine used to generate the data and an abbreviation indicating the analysis type.
</p>

<p>
  Notes :
</p>

<ul>
  <li>
    gSpiceUI has various mechanisms for managing temporary files (eg. delete them), refer to
    <a href="#MNU_SETGS">Settings&nbsp;Menu</a>.
  </li>
  <li>
    If temporary files are deleted this includes the schematic backup file.
  </li>
</ul>

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<hr size="5">

<!------------------------------------------------------------------------------------------------->

<address>
  Last modified : 2016-11-10
  <br>
  Author : Mike Waters
  <br>
  E-Mail : mwaters517_AT_gmail_DOT_com
</address>

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